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Name: Antonio R. Ledezma Arandia
Laboratory Exercise 1
DISCRETE-TIME SIGNALS: TIME-DOMAIN REPRESENTATION
1.1 GENERATION OF SEQUENCES
Project 1.1 Unit sample and unit step sequences
A copy of Program P1_1 is given below.
% Program P1_1% Generation of a Unit Sample Sequenceclf;% Generate a vector from -10 to 20n = -10:20;% Generate the unit sample sequenceu = [zeros(1,10) 1 zeros(1,20)];% Plot the unit sample sequence
stem(n,u);xlabel('Time index n');ylabel('Amplitude');title('Unit Sample Sequence');axis([-10 20 0 1.2]);
Answers:
Q1.1 The unit sample sequence u[n] generated by running Program P1_1 is shown below:
Q1.2 The purpose ofclfcommand is Limpia la ventana de la figura
The purpose ofaxiscommand is Asigna los margenes de x, y en la grafica
The purpose oftitlecommand is Coloca titulo General a nuestra grafica
The purpose ofxlabelcommand is Coloca un titulo a nuestro eje x
The purpose ofylabelcommand is - Coloca un titulo a nuestro eje y
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Q1.3 The modified Program P1_1 to generate a delayed unit sample sequence ud[n] with a dela
samples is given below along with the sequence generated by running this program .% Program P1_1
% Generation of a Unit Sample Sequenceclf;% Generate a vector from -10 to 20n = -10:20;% Generate the unit sample sequence
u = [zeros(1,10) zeros(1,11) 1 zeros(1,20-11)];% Plot the unit sample sequencestem(n,u);xlabel('Time index n');ylabel('Amplitude');title('Unit Sample Sequence');axis([-10 20 0 1.2]);
Q1.4 The modified Program P1_1 to generate a unit step sequence s[n] is given below along wsequence generated by running this program.
% Program P1_1% Generation of a Unit Sample Sequenceclf;
% Generate a vector from -10 to 20n = -10:20;% Generate the unit sample sequenceu = [zeros(1,10) zeros(1,11) 1 ones(1,20-11)];% Plot the unit sample sequencestem(n,u);xlabel('Time index n');ylabel('Amplitude');title('Unit Sample Sequence');axis([-10 20 0 1.2]);
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Q1.5 The modified Program P1_1 to generate a unit step sequence sd[n] with an advance of 7 sam
given below along with the sequence generated by running this program .
% Program P1_1% Generation of a Unit Sample Sequenceclf;% Generate a vector from -10 to 20n = -10:20;
% Generate the unit sample sequenceu = [zeros(1,10-7) 1 ones(1,20+7)];% Plot the unit sample sequencestem(n,u);xlabel('Time index n');ylabel('Amplitude');title('Unit Sample Sequence');axis([-10 20 0 1.2]);
Project 1.2 Exponential signals
A copy of Programs P1_2 and P1_3 are given below.
% Program P1_2% Generation of a complex exponential sequenceclf;c = -(1/12)+(pi/6)*i;K = 2;n = 0:40;x = K*exp(c*n);subplot(2,1,1);
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stem(n,real(x));xlabel('Time index n');ylabel('Amplitude');title('Real part');subplot(2,1,2);stem(n,imag(x));xlabel('Time index n');ylabel('Amplitude');title('Imaginary part');
Answers:
Q1.6 The complex-valued exponential sequence generated by running Program P1_2 is shown below :
Q1.7 The parameter controlling the rate of growth or decay of this sequence is -El parametroC es el que controla si: C = 1 las partes real e imaginaria son senoidales, C < corresponden a secuenciassenoidales multiplicadas por un exponencial decreciente y C>1 corresponden a secuencias senoidalesmultiplicadas por un exponencial creciente
The parameter controlling the amplitude of this sequence is la variable k
Q1.8 The result of changing the parameter c to (1/12)+(pi/6)*i is la seal sinusoidal
empieza a crecer
Q1.9 The purpose of the operator realis mostrar solo la parte real de la ecuacin
The purpose of the operatorimagis mostrar solo la parte imaginaria de la ecuacin
Q1.10 The purpose of the commandsubplot is Generar una mayor cantidad de grficos en unaventana grafica de matlab
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Q1.11 The real-valued exponential sequence generated by running Program P1_3 is shown below :
Q1.12 The parameter controlling the rate of growth or decay of this sequence is - Si a y k sonreales podemos decir que: a>1 la magnitude de la seal crece exponencialmente, a
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Project 1.3 Sinusoidal sequences
A copy of Program P1_4 is given below.
% Program P1_4% Generation of a sinusoidal sequencen = 0:40;f = 0.1;phase = 0;A = 1.5;arg = 2*pi*f*n - phase;x = A*cos(arg);clf; % Clear old graphstem(n,x); % Plot the generated sequenceaxis([0 40 -2 2]);grid;title('Sinusoidal Sequence');xlabel('Time index n');ylabel('Amplitude');axis;
Answers:
Q1.17 The sinusoidal sequence generated by running Program P1_4 is displayed below .
Q1.18 The frequency of this sequence is- 10 Hz
It is controlled by the following MATLAB command line :f = 0.1; arg = 2*pi*f*n -phase;
A sequence with new frequency _____ can be generated by the following command line
rand(1,1);
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The parameter controlling the phase of this sequence is- phase = 0; arg = 2*pi*f*n -phase;
The parameter controlling the amplitude of this sequence is-A = 1.5;
The period of this sequence is - Periodo = 1/f = 10
Q1.19 The length of this sequence is - 1.5
It is controlled by the following MATLAB command line :A = 1.5;
A sequence with new length _____ can be generated by the following command line:A =rand(1,1);
Q1.20 The average power of the generated sinusoidal sequence is- arg = 2*pi*f*n -phase;
Q1.21 The purpose ofaxiscommand is - Configurar el la ventana donde se ve el grafico en MaTlab,
los valores corresponden a: Xmin, Xmax, Ymin, Ymax
The purpose of grid command is - Generar la cuadricula en cada punto en el grafico en la
ventana de matlab
Q1.22 The modified Program P1_4 to generate a sinusoidal sequence of frequency 0.9 is given below
along with the sequence generated by running it.
% Program P1_4% Generation of a sinusoidal sequencen = 0:40;f = 0.9;Frecuencia=1/f
phase = 0;A = 1.5;arg = 2*pi*f*n - phase;x = A*cos(arg);clf; % Clear old graphstem(n,x); % Plot the generated sequenceaxis([0 40 -2 2]);grid;title('Sinusoidal Sequence');xlabel('Time index n');ylabel('Amplitude');axis;
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A comparison of this new sequence with the one generated in Question Q1.17 show
prcticamente la misma seal generada anteriormente, pero con un periodo de 1.111
A sinusoidal sequence of frequency 1.1 generated by modifying Program P1_4 is shown below.
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A comparison of this new sequence with the one generated in Question Q1.17 shows -No se distinguen los cambios, except por el periodo = 0.9091
Q1.23 The sinusoidal sequence of length 50, frequency 0.08, amplitude 2.5, and phase shift
of 90 degrees generated by modifying Program P1_4 is displayed below.
The period of this sequence is -12.5000
Q1.24 By replacing the stemcommand in Program P1_4 with theplotcommand, the plot obis as shown below:
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The difference between the new plot and the one generated in Question Q1.17 is - Elcomando plot genera graficas continuas
Q1.25 By replacing thestemcommand in Program P1_4 with thestairscommand the plot
obtained is as shown below:
The difference between the new plot and those generated in Questions Q1.17 and
Q1.24 is-El comando stairs muestra la seal como si fuse una seal digital.
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Project 1.4 Random signals
Answers:
Q1.26 The MATLAB program to generate and display a random signal of length 100 withelements uniformly distributed in the interval [2, 2] is given below along with the
plot of the random sequence generated by running the program:
sig_length = 100;r = -2 + 4.*rand(100,1);plot(1:sig_length,r);grid;
Q1.27 The MATLAB program to generate and display a Gaussian random signal of length 75with elements normally distributed with zero mean and a variance of 3 is given below
along with the plot of the random sequence generated by running the program:
x = 0:0.1:75;y = gaussmf(x,[3 20]);plot(x,y)xlabel('gaussmf, P=[3 20]')
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Q1.28 The MATLAB program to generate and display five sample sequences of a random si-
nusoidal signal of length 31
{X[n]} = {A*cos(on + )}where the amplitudeAand the phaseare statistically independent random variableswith uniform probability distribution in the range0 A 4 for the amplitude and in
the range 0 2 for the phase is given below. Also shown are five samplesequences generated by running this program five different times.
clf;f1 = 0.50;f2 = 0.60;
f3 = 0.70;f4 = 0.050;f5 = 0.080;n = 0:31;A = 4*rand(1,1);r1 = 2*pi*rand(1,1);T1 = A*cos(2*pi*f1*n+r1);plot(n,T1,'R')hold on;T1 = A*cos(2*pi*f2*n+r1);plot(n,T1,'Y')hold on;T1=A*cos(2*pi*f3*n+r1);plot(n,T1,'K')hold on;T1=A*cos(2*pi*f4*n+r1);plot(n,T1,'B')hold on;T1=A*cos(2*pi*f5*n+r1);plot(n,T1,'G')legend( 'S1[R] ','S2[Y] ','S3[K] ','S4[B] ','S5[G] ');hold off;
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1.2 SIMPLE OPERATIONS ON SEQUENCES
Project 1.5 Signal Smoothing
A copy of Program P1_5 is given below.% Program P1_5% Signal Smoothing by Averagingclf;R = 51;d = 0.8*(rand(R,1) - 0.5); % Generate random noisem = 0:R-1;s = 2*m.*(0.9.^m); % Generate uncorrupted signalx = s + d'; % Generate noise corrupted signalsubplot(2,1,1);plot(m,d','r-',m,s,'g--',m,x,'b-.');xlabel('Time index n');ylabel('Amplitude');legend('d[n] ','s[n] ','x[n] ');x1 = [0 0 x];x2 = [0 x 0];x3 = [x 0 0];y = (x1 + x2 + x3)/3;subplot(2,1,2);plot(m,y(2:R+1),'r-',m,s,'g--');legend( 'y[n] ','s[n] ');xlabel('Time index n');ylabel('Amplitude');
Answers:
Q1.29 The signals generated by running Program P1_5 are displayed below:
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Q1.30 The uncorrupted signal s[n]is - Es la seal que debemos transmitir
The additive noise d[n]is - Es una seal aleatoria
Q1.31 The statement x = s + d CAN / CANNOT be used to generate the noise corrupted
signal because - No se puede usar por que nos sale con cierta distorsion(Ruido)
Q1.32 The relations between the signalsx1, x2, and x3, and the signalxare -Son losvectores(X1, X2, X3) son los que muestrean la seal (3 vectores, se puede decir que son un tipo de filtro) y Xes la seal resultante el promedio
Q1.33 The purpose of thelegendcommand is-Sirve para poder identificar en un mismo grafico a lasdistintas seales por color y tipo de lnea.
Project 1.6 Generation of Complex Signals
A copy of Program P1_6 is given below.
% Program P1_6% Generation of amplitude modulated sequenceclf;n = 0:100;m = 0.4;fH = 0.1; fL = 0.01;xH = sin(2*pi*fH*n);xL = sin(2*pi*fL*n);
y = (1+m*xL).*xH;stem(n,y);grid;xlabel('Time index n');ylabel('Amplitude');
Answers:
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Q1.34 The amplitude modulated signals y[n]generated by running Program P1_6 for various values
of the frequencies of the carrier signal xH[n]and the modulating signal xL[n], and various
values of the modulation indexmare shown below:
Q1.35 The difference between the arithmetic operators *and.* is la diferencia esta en que si
solo se utilizer el asterisco solo se podran multiplicar numeros escalares, en cambio si utilizamos unpunto, se podra utilizar vectores.
A copy of Program P1_7 is given below.% Program P1_7
% Generation of a swept frequency sinusoidal sequencen = 0:100;a = pi/2/100;b = 0;arg = a*n.*n + b*n;x = cos(arg);clf;stem(n, x);axis([0,100,-1.5,1.5]);title('Swept-Frequency Sinusoidal Signal');xlabel('Time index n');
ylabel('Amplitude');grid; axis;
Answers:
Q1.36 The swept-frequency sinusoidal sequence x[n] generated by running Program P
displayed below.
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Q1.37 The minimum and maximum frequencies of this signal are a y b
Q1.38 The Program 1_7 modified to generate a swept sinusoidal signal with a minimum
frequency of 0.1 and a maximum frequency of 0.3 is given below:
% Program P1_7% Generation of a swept frequency sinusoidal sequence
n = 3:10;a = pi/2/100;b = 0;arg = a*n.*n + b*n;x = cos(arg);clf;stem(n, x);axis([3,10,-1.5,1.5]);title('Swept-Frequency Sinusoidal Signal');xlabel('Time index n');ylabel('Amplitude');grid; axis;
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1.3 WORKSPACE INFORMATION
Q1.39 The information displayed in the command window as a result of the whocommand i
las variables
a ans arg b n x
Q1.40 The information displayed in the command window as a result of thewhoscommand
is Muestra la informacion de cada variable.
Name Size Bytes Class Attributes
a 1x1 8 double
ans 1x4 32 double
arg 1x101 808 double
b 1x1 8 double
n 1x101 808 double
x 1x101 808 double
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1.4 OTHER TYPES OF SIGNALS (Optional)
Project 1.8 Squarewave and Sawtooth Signals
Answer:
Q1.41 MATLAB programs to generate the square-wave and the sawtooth wave sequences of the type sh
Figures 1.1 and 1.2 are given below along with the sequences generated by running these progra
n = 0:100;x = square(n);stem(n, x);axis([0,100,-1.5,1.5]);title('Swept-Frequency Sinusoidal Signal');xlabel('Time index n');ylabel('Amplitude');grid; axis;
n = 0:100;x = sawtooth(n);stem(n, x);axis([0,100,-1.5,1.5]);title('Swept-Frequency Sinusoidal Signal');xlabel('Time index n');ylabel('Amplitude');grid; axis;
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Date: 26/08/2013 Signature: DSP
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